Wireless communication terminal device, wireless communication base station device, and resource region setting method

ABSTRACT

A terminal capable of reducing the resource regions in an uplink component band without increasing signaling even if a plurality of acknowledgment signals to downlink data transmitted respectively in a plurality of downlink component bands are transmitted from one uplink component band. A terminal ( 200 ) for making communication using the plurality of downlink component bands, wherein a PCFICH reception section ( 208 ) obtains CFI information indicating the number of symbols used for a control channel to which resource allocation information relating to downlink data addressed to a device is allocated for each of the downlink component bands, a mapping section ( 214 ); sets a resource region to which an acknowledgment signal to the downlink data is allocated for each of the plurality of downlink component bands according to the CFI information of each of the downlink component bands in an uplink component band set to the device, and maps the acknowledgment signals into the resource regions corresponding to the downlink component bands used for the allocation of the downlink data.

TECHNICAL FIELD

The present invention relates to a radio communication terminalapparatus, radio communication base station apparatus and resource areasetting method.

BACKGROUND ART

3GPP-LTE (3rd Generation Partnership Project Radio Access Network LongTerm Evolution, hereinafter referred to as “LTE”) adopts OFDMA(Orthogonal Frequency Division Multiple Access) as a downlinkcommunication scheme and adopts SC-FDMA (Single Carrier FrequencyDivision Multiple Access) as an uplink communication scheme (e.g. seenon-patent literatures 1, 2 and 3).

According to LTE, a radio communication base station apparatus(hereinafter, abbreviated as “base station”) performs communication byallocating resource blocks (RB's) in a system band to a radiocommunication terminal apparatus (hereinafter, abbreviated as“terminal”) per time unit called “subframe.” Furthermore, the basestation transmits control information for notifying results of resourceallocation of downlink data and uplink data to the terminal. Thiscontrol information is transmitted to the terminal using a downlinkcontrol channel such as PDCCH (Physical Downlink Control Channel). Here,each PDCCH occupies a resource made up of one or a plurality ofcontinuous CCEs (Control Channel Elements). LTE supports a frequencyband having a width of maximum 20 MHz as a system bandwidth.

Furthermore, the PDCCH is transmitted within three initial OFDM symbolsof each subframe. Furthermore, the number of OFDM symbols used totransmit PDCCHs can be controlled in subframe units and controlled withCFI (Control Format Indicator) information notified using a PCFICH(Physical Control Format Indicator Channel) transmitted using the firstOFDM symbol of each subframe.

Furthermore, the base station simultaneously transmits a plurality ofPDCCHs to allocate a plurality of terminals to one subframe. In thiscase, the base station includes CRC bits masked (or scrambled) withdestination terminal IDs to identify the respective PDCCH destinationterminals in the PDCCHs and transmits the PDCCHs. The terminal demasks(or descrambles) the CRC bits in a plurality of PDCCHs which may bedirected to the terminal with the terminal ID of the terminal andthereby blind-decodes the PDCCHs and detects a PDCCH directed to theterminal.

Furthermore, studies are being carried out on a method of limiting CCEsto be subjected to blind decoding for each terminal for the purpose ofreducing the number of times blind decoding is performed at theterminal. This method limits a CCE area to be subjected to blinddecoding (hereinafter referred to as “search space”) for each terminal.Thus, each terminal needs to perform blind decoding only on CCEs in thesearch space allocated to that terminal and can reduce the number oftimes to perform blind decoding. Here, the search space of each terminalis set using a hash function which is a function for performingrandomization with the terminal ID of each terminal.

Furthermore, for the downlink data from the base station to theterminal, the terminal feeds back a response signal indicating the errordetection result of the downlink data (hereinafter, referred to as“ACK/NACK signal”) to the base station. The ACK/NACK signal istransmitted to the base station using an uplink control channel such asPUCCH (Physical Uplink Control Channel). Here, to eliminate thenecessity for signaling to notify a PUCCH used to transmit the ACK/NACKsignal from the base station to each terminal and efficiently usedownlink communication resources, the CCE number to which the downlinkdata is assigned is associated with the resource number of the PUCCHthat transmits the ACK/NACK signal corresponding to the downlink data.Each terminal can decide a PUCCH to use to transmit an ACK/NACK signalfrom the terminal from the CCE to which control information directed tothe terminal is mapped. The ACK/NACK signal is a 1-bit signal indicatingACK (no error) or NACK (error present), and is BPSK-modulated andtransmitted. Furthermore, the base station can freely set a resourcearea of the PUCCH to use to transmit the ACK/NACK signal and notifiesthe start resource number of the resource area of the PUCCH to allterminals located within the cell of the terminal using broadcastinformation.

Furthermore, transmission power used by the terminal for PUCCHtransmission is controlled by a PUCCH transmission power control bitincluded in the PDCCH.

Furthermore, standardization of 3GPP LTE-Advanced (hereinafter referredto as “LTE-A”) has been started which realizes further speed enhancementof communication compared to LTE. LTE-A is expected to introduce basestations and terminals (hereinafter referred to as “LTE-A terminals”)capable of communicating at a wideband frequency of 40 MHz or above torealize a maximum downlink transmission rate of 1 Gbps or above and amaximum uplink transmission rate of 500 Mbps or above. Furthermore, theLTE-A system is required to accommodate not only LTE-A terminals butalso terminals supporting the LTE system (hereinafter referred to as“LTE terminals”).

LTE-A proposes a band aggregation scheme whereby communication isperformed by aggregating a plurality of frequency bands to realizecommunication in a wideband of 40 MHz or above (e.g. see non-patentliterature 1). For example, a frequency band having a bandwidth of 20MHz is assumed to be a basic unit (hereinafter referred to as “componentband”). Therefore, LTE-A realizes a system bandwidth of 40 MHz byaggregating two component bands.

Furthermore, according to LTE-A, the base station may notify resourceallocation information of each component band to the terminal using adownlink component band of each component band (e.g. non-patentliterature 4). For example, a terminal carrying out widebandtransmission of 40 MHz (terminal using two component bands) obtainsresource allocation information of two component bands by receiving aPDCCH arranged in the downlink component band of each component band.

Furthermore, according to LTE-A, the amounts of data transmission on anuplink and downlink are assumed to be independent of each other. Forexample, there may be a case where wideband transmission (communicationband of 40 MHz) is performed on a downlink and narrowband transmission(communication band of 20 MHz) is performed on an uplink. In this case,the terminal uses two downlink component bands on the downlink and usesonly one uplink component band on the uplink. That is, asymmetriccomponent bands are used for the uplink and downlink (e.g. seenon-patent literature 5). In this case, both ACK/NACK signalscorresponding to downlink data transmitted with the two downlinkcomponent bands are transmitted to the base station using ACK/NACKresources arranged on a PUCCH of one uplink component band.

Furthermore, also when the same number of component bands are used foran uplink and downlink, as in the case of using asymmetric componentbands as described above, studies are also being carried out on apossibility that a plurality of ACK/NACK signals corresponding todownlink data transmitted in a plurality of downlink component bands maybe transmitted from one uplink component band. Here, it is independentlyset per terminal from which uplink component band of the plurality ofuplink component bands an ACK/NACK signal is transmitted.

CITATION LIST Non-Patent Literature

-   NPL 1-   3GPP TS 36.211 V8.3.0, “Physical Channels and Modulation (Release    8),” May 2008-   NPL 2-   3GPP TS 36.212 V8.3.0, “Multiplexing and channel coding (Release    8),” May 2008-   NPL 3-   3GPP TS 36.213 V8.3.0, “Physical layer procedures (Release 8),” May    2008-   NPL 4-   3GPP TSG RAN WG1 meeting, R1-082468, “Carrier aggregation    LTE-Advanced,” July 2008-   NPL 5-   3GPP TSG RAN WG1 meeting, R1-083706, “DL/UL Asymmetric Carrier    aggregation,” September 2008

SUMMARY OF INVENTION Technical Problem

When a plurality of ACK/NACK signals corresponding to downlink datatransmitted with a plurality of downlink component bands are transmittedfrom one uplink component band, it is necessary to prevent the ACK/NACKsignals corresponding to the downlink data transmitted in each downlinkcomponent band from colliding with each other. That is, in each uplinkcomponent band, it is necessary to set a PUCCH resource area fortransmission of an ACK/NACK signal (hereinafter referred to as “PUCCHarea”) for each of all downlink component bands.

Here, for a PUCCH area corresponding to each downlink component band setin each uplink component band, it is necessary to secure a resource areaenough to accommodate an ACK/NACK signal corresponding to downlink datatransmitted from each downlink component band. This is because ACK/NACKresources are associated with CCEs in a one-to-one correspondence. Forthis reason, as the number of downlink component bands increases, thenumber of PUCCH areas (number of ACK/NACK resources) that needs to besecured for each uplink component band increases, and uplink resourcesto which uplink data of the terminal is allocated (e.g. PUSCH (PhysicalUplink Shared Channel)) fall short. This may lead to a decrease inuplink data throughput.

Furthermore, the base station notifies a PUCCH area corresponding toeach downlink component band using broadcast information. Here, sincethe above PUCCH area needs to be set in a plurality of uplink componentbands, the base station notifies the PUCCH area of each downlinkcomponent band using broadcast information of the downlink componentband associated (paired) with each uplink component band. That is,information on the PUCCH areas for all downlink component bands(broadcast information) needs to be notified to each uplink componentband. For this reason, the increase in overhead of downlink broadcastinformation leads to a decrease in downlink data throughput.

It is therefore an object of the present invention to provide aterminal, base station and resource area setting method capable ofreducing PUCCH areas (number of ACK/NACK resources) in an uplinkcomponent band without increasing signaling even when a plurality ofACK/NACK signals directed to downlink data transmitted in a plurality ofdownlink component bands are transmitted from one uplink component band.

Solution to Problem

A terminal according to the present invention is a radio communicationterminal apparatus that performs communication using a plurality ofdownlink component bands, and adopts a configuration including areceiving section that obtains CFI information indicating the number ofsymbols used for a control channel to which resource allocationinformation of downlink data directed to the radio communicationterminal apparatus is allocated for each of the plurality of downlinkcomponent bands, a setting section that sets, in the uplink componentband set in the terminal apparatus, a resource area to which a responsesignal corresponding to the downlink data for each of the plurality ofdownlink component bands based on the CFI information for each of theplurality of downlink component bands and a mapping section that mapsthe response signal to the resource area corresponding to the downlinkcomponent band used to allocate the downlink data.

A base station according to the present invention adopts a configurationfor a radio communication terminal apparatus that performs communicationusing a plurality of downlink component bands, including a generatingsection that generates CFI information indicating the number of symbolsused for a control channel to which resource allocation information ofdownlink data directed to the radio communication terminal apparatus isallocated for each of the plurality of downlink component bands and areceiving section that identifies a resource area to which a responsesignal corresponding to the downlink data is allocated based on the CFIinformation for each of the plurality of downlink component bands in anuplink component band set in the radio communication terminal apparatusand extracts the response signal from the resource area corresponding tothe downlink component band used to allocate the downlink data.

A resource area setting method according to the present invention is amethod for a radio communication terminal apparatus that performscommunication using a plurality of downlink component bands, obtainingCFI information indicating the number of symbols used for a controlchannel to which resource allocation information of downlink datadirected to the radio communication terminal apparatus is allocated foreach of the plurality of downlink component bands and setting, in anuplink component band set in the radio communication terminal apparatus,a resource area to which a response signal corresponding to the downlinkdata is allocated for each of the plurality of downlink component bandsbased on the CFI information for each of the plurality of downlinkcomponent bands.

Advantageous Effects of Invention

According to the present invention, even when a plurality of ACK/NACKsignals corresponding to downlink data transmitted in each of aplurality of downlink component bands are transmitted from one uplinkcomponent band, it is possible to reduce the PUCCH areas (number ofACK/NACK resources) in an uplink component band without increasingsignaling.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram illustrating a configuration of a base stationaccording to Embodiment 1 of the present invention;

FIG. 2 is a block diagram illustrating a configuration of a terminalaccording to Embodiment 1 of the present invention;

FIG. 3 is a diagram illustrating PUCCH resources associated with eachCCE according to Embodiment 1 of the present invention;

FIG. 4 is a diagram illustrating settings of PUCCH areas according toEmbodiment 1 of the present invention;

FIG. 5 is a diagram illustrating settings of PUCCH areas according toEmbodiment 2 of the present invention (setting method 1);

FIG. 6 is a diagram illustrating settings of PUCCH areas according toEmbodiment 2 of the present invention (setting method 1);

FIG. 7 is a diagram illustrating settings of PUCCH areas according toEmbodiment 2 of the present invention (setting method 2);

FIG. 8 is a diagram illustrating settings of PUCCH areas according toEmbodiment 2 of the present invention (case with asymmetric setting);

FIG. 9 is a diagram illustrating settings of PUCCH areas according toEmbodiment 3 of the present invention; and

FIG. 10 is a diagram illustrating settings of PUCCH areas according toEmbodiment 4 of the present invention.

DESCRIPTION OF EMBODIMENTS

Hereinafter, embodiments of the present invention will be described indetail with reference to the accompanying drawings. In the followingembodiments, the same components will be assigned the same referencenumerals and overlapping explanations will be omitted.

The following descriptions assume a system whose downlink and uplink aremade up of two component bands respectively. Furthermore, a base stationallocates downlink data using PDCCHs arranged in two downlink componentbands and transmits the downlink data to a terminal. Furthermore, theterminal feeds back an ACK/NACK signal corresponding to the downlinkdata transmitted using the two downlink component bands to the basestation using a PUCCH arranged in one uplink component band.

Embodiment 1

FIG. 1 is a block diagram illustrating a configuration of base station100 according to the present embodiment.

In base station 100 shown in FIG. 1, setting section 101 sets(configures) one or a plurality of component bands to use for an uplinkand a downlink per terminal according to a required transmission rateand amount of data transmission or the like. For example, settingsection 101 sets an uplink component band and a downlink component bandto use for data transmission and an uplink component band to use forPUCCH transmission. Setting section 101 then outputs setting informationincluding the component band set in each terminal to control section102, PDCCH generation section 103 and modulation section 107.

Control section 102 generates uplink resource allocation informationindicating uplink resources (e.g. PUSCH) to which uplink data of aterminal is allocated and downlink resource allocation informationindicating downlink resources (e.g. PDSCH (Physical Downlink SharedChannel)) to which downlink data directed to the terminal is allocated.Control section 102 then outputs the uplink resource allocationinformation to PDCCH generation section 103 and extraction section 119and outputs the downlink resource allocation information to PDCCHgeneration section 103 and multiplexing section 111. Here, controlsection 102 allocates uplink resource allocation information anddownlink resource allocation information to PDCCHs arranged in downlinkcomponent bands set in each terminal based on the setting informationinputted from setting section 101. To be more specific, control section102 allocates the downlink resource allocation information to PDCCHsarranged in the downlink component bands to be subjected to resourceallocation indicated in the downlink resource allocation information.Furthermore, control section 102 allocates uplink resource allocationinformation to PDCCHs arranged in downlink component bands associatedwith the uplink component bands to be subjected to resource allocationindicated in the uplink allocation information. A PDCCH is made up ofone or a plurality of CCEs. Furthermore, the number of CCEs used by basestation 100 is set based on propagation path quality (CQI: ChannelQuality Indicator) of the allocation target terminal are and a controlinformation size so that the terminal can receive control information ata necessary and sufficient error rate. Furthermore, control section 102determines, for each component band, the number of OFDM symbols to usefor transmission of PDCCHs based on the number of CCEs to use for PDCCHsto which control information (e.g. allocation information) is allocatedin each downlink component and generates CFI information indicating thedetermined number of OFDM symbols. That is, control section 102generates, for each of the plurality of downlink component bands, CFIinformation indicating the number of OFDM symbols to use for a PDCCH towhich resource allocation information (uplink resource allocationinformation or downlink resource allocation information) of downlinkdata directed to the terminal is allocated for the terminal thatcommunicates using a plurality of downlink component bands. Controlsection 102 then outputs CFI information per downlink component band toPCFICH generation section 106, multiplexing section 111 and ACK/NACKreceiving section 122.

PDCCH generation section 103 generates a PDCCH signal including theuplink resource allocation information and downlink resource allocationinformation inputted from control section 102. Furthermore, PDCCHgeneration section 103 adds a CRC bit to the PDCCH signal to which theuplink resource allocation information and downlink resource allocationinformation have been allocated and further masks (or scrambles) the CRCbit with the terminal ID. PDCCH generation section 103 then outputs themasked PDCCH signal to modulation section 104.

Modulation section 104 modulates the PDCCH signal inputted from PDCCHgeneration section 103 after channel coding and outputs the modulatedPDCCH signal to allocation section 105.

Allocation section 105 allocates the PDCCH signal of each terminalinputted from modulation section 104 to a CCE in a search space perterminal in a downlink component band in each component band. Forexample, allocation section 105 calculates a search space of each of theplurality of downlink component bands set in each terminal from theterminal ID of each terminal, CCE number calculated using a hashfunction for performing randomization and the number of CCEs (L) makingup the search space. That is, allocation section 105 sets the CCE numbercalculated using the terminal ID of a certain terminal and a hashfunction at the starting position (CCE number) of the search space ofthe terminal and sets consecutive CCEs corresponding to the number ofCCEs L from the starting position as the search space of the terminal.Here, allocation section 105 sets the same search space (search spacemade up of CCEs of the same CCE number) between a plurality of downlinkcomponent bands set per terminal. Allocation section 105 then outputsthe PDCCH signal allocated to the CCE to multiplexing section 111.Furthermore, allocation section 105 outputs the CCE number of the CCE towhich the PDCCH signal has been allocated to ACK/NACK receiving section122.

PCFICH generation section 106 generates a PCFICH signal based on CFIinformation per downlink component band inputted from control section102. For example, PCFICH generation section 106 generates information of32 bits by coding CFI information (CFI bits) of 2 bits of each downlinkcomponent band, QPSK-modulates the generated information of 32 bits andthereby generates a PCFICH signal. PCFICH generation section 106 thenoutputs the generated PCFICH signal to multiplexing section 111.

Modulation section 107 modulates the setting information inputted fromsetting section 101, and outputs the modulated setting information tomultiplexing section 111.

Broadcast information generation section 108 sets operation parameters(system information (SIB: System Information Block)) of the cell of thebase station and generates broadcast information including the setsystem information (SIB). Here, base station 100 broadcasts systeminformation of each uplink component band using a downlink componentband associated with the uplink component band. Examples of the systeminformation of the uplink component band include PUCCH area informationindicating the starting position (resource number) of the PUCCH area touse for transmission of an ACK/NACK signal. Broadcast informationgeneration section 108 then outputs the broadcast information includingthe system information (SIB) of the cell of the base station includingthe PUCCH area information or the like to modulation section 109.

Modulation section 109 modulates the broadcast information inputted frombroadcast information generation section 108 and outputs the modulatedbroadcast information to multiplexing section 111.

Modulation section 110 modulates inputted transmission data (downlinkdata) after channel coding and outputs the modulated transmission datasignal to multiplexing section 111.

Multiplexing section 111 multiplexes the PDCCH signal inputted fromallocation section 105, PCFICH signal inputted from PCFICH generationsection 106, setting information inputted from modulation section 107,broadcast information inputted from modulation section 109 and datasignal (that is, PDSCH signal) inputted from modulation section 110.Here, multiplexing section 111 determines the number of OFDM symbols inwhich PDCCHs are arranged for each downlink component band based on theCFI information inputted from control section 102. Furthermore,multiplexing section 111 maps the PDCCH signal and data signal (PDSCHsignal) to each downlink component band based on the downlink resourceallocation information inputted from control section 102. Multiplexingsection 111 may also map the setting information to a PDSCH.Multiplexing section 111 then outputs the multiplexed signal to IFFT(Inverse Fast Fourier Transform) section 112.

IFFT section 112 transforms the multiplexed signal inputted frommultiplexing section 111 into a time waveform and CP (Cyclic Prefix)adding section 110 adds a CP to the time waveform and thereby obtains anOFDM signal.

RF transmitting section 114 applies radio transmission processing(up-conversion, D/A conversion or the like) to the OFDM signal inputtedfrom CP adding section 113 and transmits the OFDM signal via antenna115.

On the other hand, RF receiving section 116 applies radio receivingprocessing (down-conversion, A/D conversion or the like) to a receivedradio signal received in a reception band via antenna 115 and outputsthe received signal obtained to CP removing section 117.

CP removing section 114 removes a CP from the received signal and FFT(Fast Fourier Transform) section 115 transforms the received signalafter the CP removal into a frequency domain signal.

Extraction section 119 extracts uplink data of each terminal and PUCCHsignal (e.g. ACK/NACK signal) from the frequency domain signal inputtedfrom FFT section 118 based on the uplink resource allocation information(e.g. uplink resource allocation information 4 subframes ahead) inputtedfrom control section 102. IDFT (Inverse Discrete Fourier transform)section 120 transforms the signal extracted by extraction section 119into a time domain signal and outputs the time domain signal to datareceiving section 121 and ACK/NACK receiving section 122.

Data receiving section 121 decodes uplink data out of the time domainsignal inputted from IDFT section 120. Data receiving section 121outputs the decoded uplink data as received data.

ACK/NACK receiving section 122 extracts an ACK/NACK signal from eachterminal corresponding to the downlink data (PDSCH signal) out of thetime domain signal inputted from IDFT section 120. To be more specific,ACK/NACK receiving section 122 extracts, in an uplink component band setin each terminal, an ACK/NACK signal from a PUCCH (ACK/NACK resource)associated with a CCE used for the PDCCH signal out of the PUCCH areacorresponding to the downlink component band in which the PDCCH signalused to allocate the downlink data is arranged. Here, the PUCCH area isidentified from the number of CCEs available in each downlink componentband inputted from control section 102 and calculated from the CFIinformation of each downlink component band, and a downlink componentband number. Here, if base station 100 allocates a PDCCH signalincluding downlink resource allocation information of downlink data(PDSCH signal) of a plurality of component bands to CCEs of a pluralityof downlink component bands for a certain terminal, ACK/NACK receivingsection 122 extracts an ACK/NACK signal from the PUCCH (ACK/NACKresource) associated with the CCE number of the CCE used to allocate thedownlink data in the PUCCH areas corresponding to the respectivedownlink component bands. To be more specific, ACK/NACK receivingsection 122 identifies a PUCCH area to which an ACK/NACK signalcorresponding to downlink data is allocated based on the number of CCEsavailable for each of a plurality of downlink component bands calculatedbased on the CFI information for each of the plurality of downlinkcomponent bands set in the terminal in the uplink component band set inthe terminal. ACK/NACK receiving section 122 then extracts the ACK/NACKsignal from the PUCCH area corresponding to the downlink component bandused to allocate the downlink data. Thus, ACK/NACK receiving section 122obtains each ACK/NACK signal corresponding to downlink data of aplurality of component bands. ACK/NACK receiving section 122 then makesan ACK/NACK decision on the extracted ACK/NACK signal.

FIG. 2 is a block diagram illustrating a configuration of terminal 200according to the present embodiment. Terminal 200 receives a data signal(downlink data) using a plurality of downlink component bands andtransmits an ACK/NACK signal for the data signal to base station 100using a PUCCH of one uplink component band.

In terminal 200 shown in FIG. 2, RF receiving section 202 is configuredto be able to change a reception band and changes the reception bandbased on band information inputted from setting information receivingsection 207. RF receiving section 202 then applies radio receivingprocessing (down-conversion, A/D conversion or the like) to the receivedradio signal (here, OFDM signal) received in the reception band viaantenna 201 and outputs the received signal obtained to CP removingsection 203.

CP removing section 203 removes a CP from the received signal and FFTsection 204 transforms the received signal after the CP removal into afrequency domain signal. The frequency domain signal is outputted todemultiplexing section 205.

Demultiplexing section 205 demultiplexes the signal inputted from FFTsection 204 into broadcast information including system information percell including PUCCH area information indicating the PUCCH area, acontrol signal (e.g. RRC signaling) of a higher layer including settinginformation, a PCFICH signal, a PDCCH signal and a data signal (that is,PDSCH signal). Demultiplexing section 205 then outputs the broadcastinformation to broadcast information receiving section 206, outputs thecontrol signal to setting information receiving section 207, outputs thePCFICH signal to PCFICH receiving section 208, outputs the PDCCH signalto PDCCH receiving section 209 and outputs the PDSCH signal to PDSCHreceiving section 210.

Broadcast information receiving section 206 reads system information(SIB) from the broadcast information inputted from demultiplexingsection 205. Furthermore, broadcast information receiving section 206outputs PUCCH area information included in the system information of thedownlink component band associated with the uplink component band to usefor PUCCH transmission to mapping section 214. Here, the PUCCH areainformation includes the starting position (resource number) of thePUCCH area of the uplink component band and is broadcast, for example,with SIB2 (system information block type 2).

Setting information receiving section 207 reads the uplink componentband and downlink component band to use for data transmission set in theterminal and information indicating the uplink component band to use forPUCCH transmission from the control signal inputted from demultiplexingsection 205. Setting information receiving section 207 then outputs theread information to PDCCH receiving section 209, RF receiving section202 and RF transmitting section 217 as band information. Furthermore,setting information receiving section 207 reads information indicatingthe terminal ID set in the terminal from the control signal inputtedfrom demultiplexing section 205 and outputs the read information toPDCCH receiving section 209 as terminal ID information.

PCFICH receiving section 208 extracts CFI information from the PCFICHsignal inputted from demultiplexing section 205. That is, PCFICHreceiving section 208 obtains the CFI information indicating the numberof OFDM symbols to use for a PDCCH to which resource allocationinformation of downlink data directed to the terminal is allocated foreach of the plurality of downlink component bands set in the terminal.PCFICH receiving section 208 then outputs the extracted CFI informationto PDCCH receiving section 209 and mapping section 214.

PDCCH receiving section 209 blind-decodes the PDCCH signal inputted fromdemultiplexing section 205 and obtains a PDCCH signal (resourceallocation information) directed to the terminal. Here, the PDCCH signalis allocated to each CCE (that is, PDCCH) arranged in the downlinkcomponent band set in the terminal indicated in the band informationinputted from setting information receiving section 207. To be morespecific, PDCCH receiving section 209 identifies the number of OFDMsymbols in which the PDCCH is arranged for each downlink component bandbased on the CFI information inputted from PCFICH receiving section 208.PDCCH receiving section 209 then calculates a search space of theterminal using the terminal ID of the terminal indicated in the terminalID information inputted from setting information receiving section 207.All search spaces (CCE numbers of CCEs constituting the search space)calculated here are the same between a plurality of downlink componentbands set in the terminal. PDCCH receiving section 209 then demodulatesand decodes the PDCCH signal allocated to each CCE in the calculatedsearch space. PDCCH receiving section 209 demasks a CRC bit with theterminal ID of the terminal indicated in the terminal ID information forthe decoded PDCCH signal and thereby decides the PDCCH signal whichresults in CRC=OK (no error) to be a PDCCH signal directed to theterminal. PDCCH receiving section 209 performs the above-described blinddecoding on each component band to which a PDCCH signal has beentransmitted and thereby acquires resource allocation information of thecomponent band. PDCCH receiving section 209 outputs downlink resourceallocation information included in the PDCCH signal directed to theterminal to PDSCH receiving section 210 and outputs uplink resourceallocation information to mapping section 214. Furthermore, PDCCHreceiving section 209 outputs the CCE number of the CCE (CCE resultingin CRC=OK) from which the PDCCH signal directed to the terminal isdetected in each component band to mapping section 214. When a pluralityof CCEs are used for one PDCCH signal, PDCCH receiving section 209outputs the start (smallest number) CCE number to mapping section 214.

PDSCH receiving section 210 extracts received data (downlink data) fromthe PDSCH signals of a plurality of downlink component bands inputtedfrom demultiplexing section 205 based on the downlink resourceallocation information of the plurality of downlink component bandsinputted from PDCCH receiving section 209. Furthermore, PDSCH receivingsection 210 performs error detection on the extracted received data(downlink data). When the error detection result shows that an error isfound in the received data, PDSCH receiving section 210 generates a NACKsignal as the ACK/NACK signal, whereas when no error is found in thereceived data, PDSCH receiving section 210 generates an ACK signal asthe ACK/NACK signal and outputs the ACK/NACK signal to modulationsection 211. When base station 100 transmits two data blocks (TransportBlocks) by spatially multiplexing PDSCH transmission through MIMO(Multiple-Input Multiple-Output) or the like, PDSCH receiving section210 generates ACK/NACK signals for the respective data blocks.

Modulation section 211 modulates the ACK/NACK signal inputted from PDSCHreceiving section 210. When base station 100 transmits two data blocksby spatially multiplexing the PDSCH signal in each downlink componentband, modulation section 211 applies QPSK modulation to the ACK/NACKsignal. On the other hand, when base station 100 transmits one datablock, modulation section 211 applies BPSK modulation to the ACK/NACKsignal. That is, modulation section 211 generates one QPSK signal orBPSK signal as the ACK/NACK signal per downlink component band.Modulation section 211 then outputs the modulated ACK/NACK signal tomapping section 214.

Modulation section 212 modulates transmission data (uplink data) andoutputs the modulated data signal to DFT (Discrete Fourier transform)section 213.

DFT section 213 transforms the data signal inputted from modulationsection 212 into a frequency domain signal and outputs the plurality offrequency components obtained to mapping section 214.

Mapping section 214 maps the data signal inputted from DFT section 213to PUSCHs arranged in the uplink component band according to the uplinkresource allocation information inputted from PDCCH receiving section209. Furthermore, mapping section 214 maps the ACK/NACK signal inputtedfrom modulation section 211 to the PUCCHs arranged in the uplinkcomponent band according to the PUCCH area information (informationindicating the starting position of the PUCCH area) inputted frombroadcast information receiving section 206, CFI information perdownlink component band inputted from PCFICH receiving section 208 andthe CCE number inputted from inputted from PDCCH receiving section 209.That is, mapping section 214 sets, in the uplink component band set inthe terminal, the PUCCH area to which the ACK/NACK signal is allocatedfor every plurality of downlink component bands based on the number ofCCEs available for every plurality of downlink component bandscalculated based on the CFI information for every plurality of downlinkcomponent bands set in the terminal. Mapping section 214 then maps theACK/NACK signal to the PUCCH area corresponding to the downlinkcomponent band used to allocate the downlink data (that is, ACK/NACKresources associated with the CCE of the CCE number inputted from PDCCHreceiving section 209).

For example, as shown in FIG. 3, ACK/NACK resources (A/Ns #0 to #17) ofthe PUCCH are defined by a primary spreading sequence (amount of cyclicshift of ZAC (Zero Auto Correlation) sequence) and a secondary spreadingsequence (blockwise spreading code such as Walsh sequence). Here,ACK/NACK resource numbers are associated with CCE numbers in aone-to-one correspondence and mapping section 214 allocates ACK/NACKsignals to the primary spreading sequence and secondary spreadingsequence associated with the CCE number inputted from PDCCH receivingsection 209. Furthermore, when a PDSCH signal is transmitted in aplurality of downlink component bands, mapping section 214 allocatesACK/NACK signals corresponding to the PDSCH signals transmitted in therespective downlink component bands to ACK/NACK resources associatedwith the CCEs used to allocate the PDSCH signal out of the PUCCH areacorresponding to the downlink component band in which the PDCCH used toallocate the PDSCH signal is arranged.

Modulation section 211, modulation section 212, DFT section 213 andmapping section 214 may be provided for each component band.

IFFT section 215 transforms a plurality of frequency components mappedto the PUSCH into a time domain waveform, and CP adding section 216 addsa CP to the time domain waveform.

RF transmitting section 217 is configured to be able to change atransmission band and sets a transmission band based on the bandinformation inputted from setting information receiving section 207. RFtransmitting section 217 then applies radio transmission processing(up-conversion, D/A conversion or the like) to the signal with a CPadded and transmits the signal via antenna 201.

Next, details of operations of base station 100 and terminal 200 will bedescribed.

In the following descriptions, setting section 101 of base station 100(FIG. 1) sets, in terminal 200, two downlink component bands (componentband 0 and component band 1) and one uplink component band (componentband 0) of the system in which a downlink and an uplink shown in FIG. 4are each made up of two component bands. Therefore, terminal 200transmits an ACK/NACK signal to base station 100 using the resourceareas (ACK/NACK resources) of the PUCCHs arranged in the uplinkcomponent band of component band 0 associated with the CCE used toallocate a PDSCH signal irrespective of in which downlink component bandthe PDSCH signal has been received. In FIG. 4, the PUCCH areas are setat both ends of the uplink component band and one PUCCH ishopping-transmitted in the first-half and second-half portions of onesubframe. Therefore, only one area will be described as the PUCCH areabelow.

Furthermore, the PDCCH arranged in each downlink component band shown inFIG. 4 is made up of a plurality of CCEs (CCE #1, CCE #2, CCE #3 . . .). Furthermore, each ACK/NACK resource such as ACK/NACK resource #1 to#(k+j) shown in FIG. 4 corresponds, for example, to ACK/NACK resource(A/N #0 to #17) shown in FIG. 3. Each ACK/NACK resource (A/N #0 to #17)shown in FIG. 3 represents an ACK/NACK resource corresponding to one RBand a plurality of RBs are used to provide 18 or more ACK/NACKresources. Furthermore, when a plurality of RBs are used, ACK/NACKresource numbers are sequentially numbered from RBs at both ends of theband toward the center.

Furthermore, as shown in FIG. 4, of the CFI information allocated toPCFICH resources of each downlink component band, suppose the CFIinformation indicating the number of OFDM symbols in which a PDCCH isarranged in the downlink component band of component band 0 is CFI0 andthe CFI information indicating the number of OFDM symbols in which aPDCCH is arranged in the downlink component band of component band 1 isCFI1. CFI0 and CFI1 take one of values 1 to 3 (that is, 1 to 3 OFDMsymbols). Here, as shown in FIG. 4, control section 102 of base station100 assumes the number of CCEs available in the downlink component bandof component band 0 is k (CCEs #1 to #k) and CFI0 in component band 0 isL. Furthermore, control section 102 assumes the number of CCEs availablein the downlink component band of component band 1 is j (CCEs #1 to #j).

Allocation section 105 of base station 100 (FIG. 1) allocates a PDCCHsignal of each downlink component band to one of CCEs #1 to #k of thedownlink component band of component band 0 and CCEs #1 to #j of thedownlink component band of component band 1 set in terminal 200.

Furthermore, broadcast information generation section 108 of basestation 100 generates system information indicating the startingposition (resource number) of the PUCCH area of the uplink componentband of component band 0 associated with the downlink component band ofcomponent band 0. Furthermore, broadcast information generation section108 generates system information indicating the starting position(resource number) of the PUCCH area of the uplink component band ofcomponent band 1 associated with the downlink component band ofcomponent band 1. For example, the system information is included inSIB2.

Broadcast information receiving section 206 of terminal 200 reads thestarting position (resource number) of the PUCCH area in the uplinkcomponent band associated with each downlink component band included inthe system information (SIB2) of component band 0 and component band 1shown in FIG. 4. That is, broadcast information receiving section 206reads the starting position of the PUCCH area in the uplink componentband of component band 0 from SIB2 (not shown) of the downlink componentband of component band 0 shown in FIG. 4 and reads the starting positionof the PUCCH area in the uplink component band of component band 1 fromSIB2 (not shown) of the downlink component band of component band 1shown in FIG. 4.

Furthermore, PCFICH receiving section 208 extracts CFI0 (=L) from thePCFICH signal allocated to the PCFICH resource of component band 0 shownin FIG. 4 and extracts CFI1 from the PCFICH signal allocated to thePCFICH resource of component band 1.

PDCCH receiving section 209 then identifies the number of OFDM symbolsin which PDCCHs are arranged in the downlink component band of componentband 0 based on CFI0 and identifies the number of OFDM symbols in whichPDCCHs are arranged in the downlink component band of component bandbased on CFI1. PDCCH receiving section 209 then blind-decodes the CCEsin search spaces (not shown) of component band 0 and component band 1and identifies the CCEs to which the PDCCH signal (resource allocationinformation) directed to the terminal is allocated. Here, there may be aplurality of CCEs to which the PDCCH signal (resource allocationinformation) directed to the terminal is allocated. Thus, as shown inFIG. 4, PDCCH receiving section 209 decides PDCCH signals allocated toone or a plurality of CCEs of CCEs #1 to #k of the downlink componentband of component band 0 and PDCCH signals allocated to one or aplurality of CCEs of CCEs #1 to #j of the downlink component band ofcomponent band 1 as PDCCH signals directed to the terminal.

Furthermore, mapping section 214 maps ACK/NACK signals corresponding tothe downlink data allocated using one or a plurality of CCEs of CCEs #1to #k of component band 0 in the uplink component band of component band0 shown in FIG. 4 and ACK/NACK signals corresponding to the downlinkdata allocated using one or a plurality of CCEs of CCEs #1 to #j ofcomponent band 1 to the PUCCH area corresponding to the downlinkcomponent band used to allocate each piece of downlink data.

Here, the PUCCH areas (ACK/NACK resources) to use for transmission ofACK/NACK signals for the downlink data allocated using CCEs of eachdownlink component band are calculated according to the number of CCEsavailable in each downlink component band calculated based on the CFIinformation (here, CFI0 and CFI1) and the CCE number of the CCE used toallocate the downlink data (start CCE number when a plurality of CCEsare used). To be more specific, the number of CCEs N_(CCE)(i) availablein a downlink component band of component band i in a certain subframeis calculated according to following equation 1.

N _(CCE)(i)=(L(i)*N _(RE) _(—) _(total) −N _(RS) −N _(PCFICH) −N_(PHICH)/) N _(RE) _(—) _(CCE)  (Equation 1)

Here, i represents a component band number (i=0, 1 in FIG. 4) of acomponent band. Furthermore, L(i) represents CFI information (here,L(i)=1 to 3) of a downlink component band (component band i) in acertain subframe, N_(RE) _(—) _(total) represents the number of REs(Resource Elements) included in 1 OFDM symbol, N_(RS) represents thenumber of REs used for reference signals included in L(i) OFDM symbols,N_(PCFICH) represents the number of REs used for the PCFICH signalincluded in L(i) OFDM symbols, N_(PHICH) represents the number of REsused for the PHICH (Physical Hybrid-ARQ Indicator Channel) signal(downlink ACK/NACK signal) included in L(i) OFDM symbols and N_(RE) _(—)_(CCE) represents the number of REs per CCE. For example, according toLTE, N_(PCFICH)=16 and N_(RE) _(—) _(CCE) ⁼36. Furthermore, N_(RS)depends on the number of antenna ports and can be calculated by terminal200. Furthermore, N_(PHICH) can be calculated by terminal 200 from PHICHinformation notified with broadcast information. Furthermore, terminal200 uses, for example, a value 4 subframes ahead of the transmissiontiming of an ACK/NACK signal as L(i). This is because the terminalperforms decoding processing or the like on the received PDCCH signaland PDSCH signal and then transmits an ACK/NACK signal 4 subframeslater. Furthermore, an RE is a resource unit representing 1 subcarrierwithin one OFDM symbol.

For example, the number of CCEs N_(CCE)(i) available in each componentband i (where i=0,1) shown in FIG. 4 calculated by equation 1 isN_(CCE)(0)=k and N_(CCE)(1)=j.

An ACK/NACK signal corresponding to the downlink data allocated using aCCE of the downlink component band in component band i in a certainsubframe is mapped to PUCCH resource (ACK/NACK resource number)n_(PUCCH) calculated according to next equation 2.

n _(PUCCH) =N _(PUCCH)+Σ_(m=0) ^(i=1) N _(CCE)(m)+n _(CCE)(i)  (Equation2)

Here, N_(PUCCH) represents the starting position (resource number) ofthe PUCCH area corresponding to the downlink component band of componentband i notified with SIB2 of the downlink component band of componentband i and n_(CCE)(i) represents the CCE number of a CCE used for PDCCHtransmission in the downlink component band of component band (i+1). Acase has been described with equation 2 where the starting positionN_(PUCCH) of the PUCCH area notified with SIB2 is used, but N_(PUCCH) isunnecessary in equation 2 when PUCCH resources (ACK/NACK resources) touse for transmission of ACK/NACK signals is defined based on a relativeposition from the starting position of the entire PUCCH area arranged inthe uplink component band.

For example, for each component band i (where i=0, 1) shown in FIG. 4,CCE number n_(CCE)(i) in equation 2 is n_(CCE)(0)=1 to k andn_(CCE)(1)=1 to j.

Thus, as shown in FIG. 4, mapping section 214 sets k ACK/NACK resources#1 to #k from the starting position N_(PUCCH) of the PUCCH areacorresponding to the downlink component band of component band 0notified with SIB2 of the downlink component band of component band 0according to equation 2 as the PUCCH area corresponding to the downlinkcomponent band of component band 0. That is, as shown in FIG. 4,ACK/NACK resources #1 to #k are associated with CCEs #1 to #k of thedownlink component band of component band 0.

Next, as shown in FIG. 4, mapping section 214 identifies the startingposition (N_(PUCCH)+N_(CCE)(0)) of the PUCCH area corresponding to thedownlink component band of component band 1 according to equation 2based on the number of CCEs N_(CCE)(0)=k calculated according toequation 1 and the starting position N_(PUCCH) of the PUCCH area ofcomponent band 0. Mapping section 214 then sets j ACK/NACK resources#(k+1) to #(k+j) from the starting position (N_(PUCCH)+N_(CCE)(0))according to equation 2 as the PUCCH area corresponding to the downlinkcomponent band of component band 1. That is, as shown in FIG. 4,ACK/NACK resources #(k+1) to #(k+j) are associated with CCEs #1 to #j ofthe downlink component band of component band 1 respectively.

Mapping section 214 then maps ACK/NACK signals corresponding to thedownlink data allocated using CCEs #1 to #k of component band 0 shown inFIG. 4 to ACK/NACK resources #1 to #k in the PUCCH area directed tocomponent band 0. Furthermore, as shown in FIG. 4, mapping section 214maps ACK/NACK signals corresponding to the downlink data allocated usingCCEs #1 to #j of component band 1 to ACK/NACK resources #(k+1) to #(k+j)in the PUCCH area directed to component band 1. That is, mapping section214 sets the starting position of the PUCCH area corresponding to thedownlink component band of component band 1 to be variable based on CFIinformation (CFI0 in FIG. 4), that is, the number of CCEs available inthe downlink component band of component band 0. In other words, mappingsection 214 sets the end position of the PUCCH area corresponding to thedownlink component band of component band 0 to be variable based on CFIinformation (CFI0 in FIG. 4), that is, the number of CCEs available inthe downlink component band of component band 0. To be more specific,mapping section 214 secures the PUCCH area corresponding to the downlinkcomponent band of component band 0 by the number corresponding to thenumber of CCEs available in the downlink component band of componentband 0.

On the other hand, ACK/NACK receiving section 122 of base station 100calculates the number of CCEs N_(CCE) of each downlink component bandaccording to equation 1 based on CFI0 and CFI1 inputted from controlsection 102 as in the case of terminal 200. ACK/NACK receiving section122 then sets the PUCCH area (ACK/NACK resources #1 to #k shown in FIG.4) corresponding to the downlink component band of component band 0 andthe PUCCH area (ACK/NACK resources #(k+1) to #(k+j) shown in FIG. 4)corresponding to the downlink component band of component band 1 as inthe case of terminal 200. ACK/NACK receiving section 122 then extractsACK/NACK signals corresponding to the PDSCH signal of each downlinkcomponent band from ACK/NACK resources associated with the CCE number ofthe CCE to which the PDCCH signal is allocated in the PUCCH areacorresponding to each downlink component band.

Thus, terminal 200 controls, in the uplink component band set in theterminal, the starting position of the PUCCH area corresponding to eachdownlink component band per subframe based on the number of CCEs (thenumber of CCEs that can be transmitted by base station 100) available ineach downlink component band calculated based on the CFI information ofeach downlink component band set in the terminal.

Here, ACK/NACK resources necessary for PUCCHs arranged in each uplinkcomponent band depend on the number of CCEs used in PDCCHs arranged ineach downlink component band. Furthermore, the number of CCEs used forthe PDCCHs arranged in each downlink component band differs from onesubframe to another. That is, in each uplink component band, the PUCCHarea corresponding to each downlink component band (the number ofACK/NACK resources associated with the CCEs of each downlink componentband) differs from one subframe to another.

However, terminal 200 controls the starting position of the PUCCH areacorresponding to each downlink component band by calculating the numberof CCEs available in each downlink component band based on CFIinformation notified for every subframe. Thus, terminal 200 can securethe number of ACK/NACK resources corresponding to the number of CCEsavailable in each downlink component band (the number of CCEs that canbe transmitted by base station 100) for every subframe. That is,terminal 200 can secure the number of CCEs available in each downlinkcomponent band, that is, ACK/NACK resources corresponding to the numberof CCEs used to allocate for the PDSCH signal in each downlink componentband. That is, in the uplink component band of component band 0 shown inFIG. 4, terminal 200 secures only necessary minimum ACK/NACK resourcesin both downlink component bands of component band 0 and component band1.

Thus, according to the present embodiment, the terminal calculates thenumber of CCEs available in each downlink component band based on theCFI information notified from the base station for every subframe andcontrols the PUCCH area corresponding to each downlink component bandbased on the calculated number of CCEs. Thus, the terminal can secure,for every subframe, the necessary minimum PUCCH areas (ACK/NACKresources) corresponding to each downlink component band set in theterminal in the uplink component band set in the terminal. Furthermore,the terminal controls the PUCCH area based on the system information(SIB), which is existing signaling in LTE, and CFI information. That is,according to the present embodiment, signaling from the base station tothe terminal need not be newly added for LTE-A. Thus, according to thepresent embodiment, even when a plurality of ACK/NACK signalscorresponding to downlink data transmitted through a plurality ofdownlink component bands respectively are transmitted from one uplinkcomponent band, it is possible to reduce the PUCCH areas (number ofACK/NACK resources) in the uplink component band without increasingsignaling.

Furthermore, according to the present embodiment, it is possible tosecure more PUSCH resources by minimizing the PUCCH areas that need tobe secured in the uplink component band and thereby improve uplink datathroughput. Furthermore, signaling need not be newly added in thedownlink component band and the number of PDCCH resources does notincrease, and it is thereby possible to prevent the downlink datathroughput from decreasing.

Furthermore, according to the present embodiment, the terminal arrangesall PUCCH areas in one place together by causing PUCCH areascorresponding to the respective downlink component bands to neighboreach other in the uplink component band set in the terminal. For thisreason, the terminal can allocate more continuous resources (RB) to aPUSCH signal. Here, when the base station allocates continuous RBs whenallocating a PUSCH signal to the terminal, the base station needs onlyto notify the starting RB number and the number of RBs (or ending RBnumber), and can thereby reduce the number of notification bits tonotify resource allocation and improve the resource allocationefficiency.

Furthermore, as in the case of, for example, LTE-A, when each downlinkcomponent band is a wideband (e.g. 20-MHz band), it may not be necessaryto secure a maximum number of CCEs of each downlink component band whichare secured with a maximum number of OFDM symbols (here, 3 OFDMsymbols). This is because when each downlink component band is awideband, there are many resources per OFDM symbol available for PDCCHs.That is, for many subframes, the probability is small that 3 OFDMsymbols which is the maximum number of OFDM symbols (CFI information)used for a PDCCH will be required. That is, base station 100 canallocate a sufficient number of CCEs to a plurality of terminals withoutsecuring the maximum number of CCEs and secure sufficient frequencyscheduling effects. For example, when a maximum of 80 CCEs can besecured with a 20-MHz downlink component band in 1 subframe, basestation 100 may secure only 40 CCEs, half the maximum number of CCEs.Thus, terminal 200 needs to secure PUCCH areas for only 40 CCEs, halfthe number of CCEs calculated based on CFI information, and can therebyreduce the PUCCH areas and improve the throughput of uplink data.

The present embodiment has described the setting of PUCCHs in the uplinkcomponent band of component band 0 shown in FIG. 4 as an example of thesetting of PUCCH areas. However, the present invention performs asetting of PUCCH areas also for PUCCHs in the uplink component band ofcomponent band 1 shown in FIG. 4 as in the case of the above embodiment.

Embodiment 2

The present embodiment sets a PUCCH area corresponding to a downlinkcomponent band associated with an uplink component band set in aterminal out of a plurality of downlink component bands set in theterminal at an end of the uplink component band than the PUCCH areacorresponding to the downlink component band rather other than thedownlink component band associated with the uplink component band.

Hereinafter, the present embodiment will be described more specifically.In the following descriptions, an uplink component band of componentband i (where i is a component band number) is associated with adownlink component band of component band i. Here, the uplink componentband associated with the downlink component band is notified withbroadcast information of the downlink component band. Furthermore, PUCCHarea information (PUCCH config shown in FIG. 5) indicating the startingposition of the PUCCH area corresponding to the downlink component bandof component band i in the uplink component band of component band i isnotified from base station 100 (FIG. 1) to terminal 200 (FIG. 2) withbroadcast information including system information (SIB2) allocated tothe downlink component band of component band i.

For example, in FIG. 5, broadcast information generation section 108 ofbase station 100 sets system information (SIB2) indicating the startingposition (resource number) of the PUCCH area corresponding to thedownlink component band of component band 0 (component band 1) in theuplink component band of component band 0 (component band 1) in thedownlink component band of component band 0 (component band 1).

Hereinafter, setting methods 1 and 2 of PUCCH areas (ACK/NACK resources)will be described.

<Setting Method 1>

In the present setting method, in the uplink component band set in theterminal, terminal 200 sets PUCCH areas corresponding to a plurality ofdownlink component bands in predetermined order of downlink componentbands (component band numbers) from the downlink component bandassociated with the uplink component band out of a plurality of downlinkcomponent bands set in the terminal sequentially from the startingposition of the resource area broadcast with a downlink component bandassociated with the uplink component band.

Here, setting section 101 of base station 100 (FIG. 1) sets two downlinkcomponent bands (component band 0 and component band 1) and one uplinkcomponent band (component band 0) of the system whose downlink anduplink shown in FIG. 5 are made up of two component bands respectivelyin terminal 1 and sets two downlink component bands (component band 0and component band 1) and one uplink component band (component band 1)in terminal 2. Here, terminal 1 and terminal 2 are provided with thesame configuration as that of terminal 200 (FIG. 2) in Embodiment 1.

Furthermore, as shown in FIG. 5 as in the case of Embodiment 1 (FIG. 4),suppose CFI information of component band 0 is CFI0 and CFI informationof component band 1 is CFI1. Furthermore, as in the case of Embodiment 1(FIG. 4), suppose the number of CCEs available in the downlink componentband of component band 0 is k (CCEs #1 to #k) and the number of CCEsavailable in the downlink component band of component band 1 is j (CCEs#1 to #j) as shown in FIG. 5.

Therefore, allocation section 105 of base station 100 (FIG. 1) allocatesa PDCCH signal of each terminal to one of CCEs #1 to #k of the downlinkcomponent band of component band 0 and CCEs #1 to #j of the downlinkcomponent band of component band 1 set in terminal 1 and terminal 2.

In the uplink component band of component band 0 or component band 1shown in FIG. 5, each mapping section 214 of terminal 1 and terminal 2maps ACK/NACK signals for downlink data allocated using CCEs #1 to #k ofcomponent band 0 respectively and ACK/NACK signals for downlink dataallocated using CCEs #1 to #j of component band 1 respectively to PUCCHareas corresponding to the downlink component band used to allocate eachpiece of downlink data.

Here, PUCCH areas (ACK/NACK resources) used to transmit ACK/NACK signalscorresponding to the downlink data allocated using CCEs of each downlinkcomponent band are sequentially set in order of component band numbersfrom a downlink component band associated with each uplink componentband from an end of each uplink component band (that is, the startingposition of the PUCCH area broadcast in the downlink component bandassociated with each uplink component band).

To be more specific, in the uplink component band of component band i,PUCCH areas corresponding to the respective downlink component bands areset in order of component band(i), component band((i+1)mod N_(cc)),component band ((i+2)mod N_(cc)), . . . , component band((i+N_(cc)−1)mod N_(cc)) from the starting position of the PUCCH areanotified with SIB2 of the downlink component band of component band i.Where “operation mod” represents modulo operation and N_(cc) representsthe number of downlink component bands.

That is, as shown in FIG. 5, mapping section 214 of terminal 1 sets kACK/NACK resources #1 to #k from the starting position of the PUCCH areacorresponding to the downlink component band of component band 0notified with SIB2 of the downlink component band of component band 0 inthe uplink component band of component band 0 as the PUCCH areacorresponding to the downlink component band of component band 0. Next,as in the case of Embodiment 1, as shown in FIG. 5, mapping section 214of terminal 1 sets j ACK/NACK resources #(k+1) to #(k+j) from thestarting position (#(k+1)) of the PUCCH area corresponding to thedownlink component band of component band 1 (=(0+1)mod 2) as the PUCCHarea corresponding to the downlink component band of component band 1.That is, as shown in FIG. 5, in order of the downlink component band ofcomponent band 0 and the downlink component band of component band 1,PUCCH areas corresponding to the respective downlink component bands aresequentially set from an end of the uplink component band of componentband 0 (that is, starting position of the PUCCH area broadcast with SIB2of the downlink component band of component band 0).

On the other hand, as shown in FIG. 5, mapping section 214 of terminal 2sets j ACK/NACK resources #1 to #j from the starting position of thePUCCH area corresponding to the downlink component band of componentband 1 notified by SIB2 of the downlink component band of component band1 in the uplink component band of component band 1 as the PUCCH areacorresponding to the downlink component band of component band 1. Next,mapping section 214 of terminal 2 sets k ACK/NACK resources #(j+1) to#(j+k) from the starting position (#(j+1)) of the PUCCH areacorresponding to the downlink component band of component band 0(=(1+1)mod 2) as the PUCCH area corresponding to the downlink componentband of component band 0 as shown in FIG. 5. That is, as shown in FIG.5, in order of the downlink component band of component band 1 and thedownlink component band of component band 0, the PUCCH areascorresponding to the respective downlink component bands are set inorder from an end of the uplink component band of component band 1 (thatis, starting position of the PUCCH area broadcast with SIB2 of thedownlink component band of component band 1).

That is, in each uplink component band, the PUCCH area corresponding tothe downlink component band associated with each uplink component bandis set at the end of the uplink component band rather than the PUCCHarea corresponding to the downlink component band other than thedownlink component band associated with the uplink component band. Then,the PUCCH areas corresponding to the downlink component band other thanthe downlink component bands associated with the uplink component bandare sequentially set from the band (that is, the end of the uplinkcomponent band) in which PUCCHs corresponding to the downlink componentband associated with each uplink component band are set toward thecenter frequency (that is, inside the uplink component band) of theuplink component band. Here, each terminal (terminal 200) controls thestarting position of the PUCCH areas corresponding to the downlinkcomponent band other than the downlink component band associated witheach uplink component band for every subframe based on the CFIinformation of each downlink component band as in the case of Embodiment1.

In LTE-A, not only LTE-A terminals but also LTE terminals are requiredto be accommodated. Here, one uplink component band and one downlinkcomponent band are set in an LTE terminal. Furthermore, in that case,the uplink component band and downlink component band associated witheach other are always set in the LTE terminal. That is, in the uplinkcomponent band set in the LTE terminal, the PUCCH areas used by the LTEterminal are fixedly set with SIB2 (broadcast information) of thedownlink component band associated with the uplink component band.

In the uplink component band used by the LTE terminal according to thepresent setting method, the PUCCH area corresponding to the downlinkcomponent band (downlink component band used by the LTE terminal)associated with the uplink component band is always arranged at an endof the uplink component band. The PUCCH areas corresponding to thedownlink component bands (e.g. downlink component band used only by theLTE-A terminal) other than the downlink component band associated withthe uplink component band used by the LTE terminal are arranged insidethe uplink component band rather than the PUCCH area corresponding tothe downlink component band used by the LTE terminal based on CFIinformation. Thus, it is possible to continuously arrange the respectivePUCCH areas corresponding to a plurality of downlink component bandsfrom the end of the uplink component band toward the carrier frequency(center frequency) of the uplink component band.

That is, as in the case of Embodiment 1, terminal 200 can set thestarting position of PUCCH areas corresponding to the downlink componentband other than the downlink component band associated with the uplinkcomponent band used by the LTE terminal to be variable based on the CFIinformation and set the PUCCH areas in continuous bands from the end ofthe uplink component band set in the terminal without any gap.Therefore, according to the present setting method, it is possible tominimize PUCCH areas as in the case of Embodiment 1.

Thus, according to the present setting method, it is possible to reducePUCCH areas as in the case of Embodiment 1 while supporting LTEterminals in each uplink component band even when LTE-A terminals andLTE terminals coexist.

Furthermore, according to the present setting method, in a certainuplink component band, a PUCCH area whose starting position iscontrolled according to CFI information (e.g. PUCCH area correspondingto a downlink component band used only by LTE-A terminals) is arrangedto be variable inside the PUCCH area corresponding to the downlinkcomponent band corresponding to the uplink component band. Thus, evenwhen the amount of PUCCH resources is small because, for example, CFIinformation is small, PUCCH areas are always arranged together at an endof an uplink component band. For this reason, according to the presentsetting method, it is possible to secure resources of continuouswidebands as PUSCH resources and improve resources allocationefficiency.

Furthermore, according to the present setting method, the terminal setsPUCCH areas in order of component bands preset in each uplink componentband based on the starting position of the PUCCH area notified with SIB2of the downlink component band associated with the uplink component bandand the number of downlink component bands N_(cc) of the system. Thus,the terminal can uniformly identify PUCCH areas corresponding to alldownlink component bands using only existing control information, makingnew signaling unnecessary.

A case has been described in the present setting method where the numberof component bands of the system is two (FIG. 5). However, in thepresent invention, the number of component bands of the system is notlimited to two. For example, a case where the number of component bandsof the system is three will be described using FIG. 6. As shown in FIG.6, in an uplink component band of component band 0, PUCCH areascorresponding to the respective downlink component bands of componentband 0, component band 1 and component band 2 are set in order from theend of the uplink component band (starting position of the PUCCH areanotified with SIB2 of component band 0). Similarly, as shown in FIG. 6,in the uplink component band of component band 1, PUCCH areascorresponding to the respective downlink component bands of componentband 1, component band 2 and component band 0 are set in order from theend of the uplink component band (starting position of the PUCCH areanotified with SIB2 of component band 1). The same applies to the uplinkcomponent band of component band 2.

<Setting Method 2>

In the present setting method, in an uplink component band set in theterminal, terminal 200 sets PUCCH areas corresponding to a plurality ofdownlink component bands from an end of the uplink component band inorder of closeness to the carrier frequency of the downlink componentband associated with uplink component bands from the downlink componentbands associated with uplink component bands of a plurality of downlinkcomponent bands set in the terminal.

In the following descriptions, a case where the number of componentbands of the system is three will be described.

For example, as shown in FIG. 7, in an uplink component band ofcomponent band 0, PUCCH areas corresponding to respective downlinkcomponent bands are set in order of component band 0, component band 1and component band 2 from the end of the uplink component band (thestarting position of a PUCCH area of component band 0 notified withSIB2). That is, terminal 200 in which the uplink component band ofcomponent band 0 is set sets PUCCH areas from the end of the uplinkcomponent band of component band 0 in order of the PUCCH areacorresponding to the downlink component band of component band 0, thePUCCH area corresponding to the downlink component band of componentband 1 closest to the carrier frequency of the downlink component bandof component band 0 and the PUCCH area corresponding to the downlinkcomponent band of component band 2 farthest from the carrier frequencyof the downlink component band of component band 0.

On the other hand, as shown in FIG. 7, in the uplink component band ofcomponent band 2, PUCCH areas corresponding to the respective downlinkcomponent bands are set in order of component band 2, component band 1and component band 0 from the end of the uplink component band (thestarting position of a PUCCH area of component band 2 notified withSIB2). That is, terminal 200 in which the uplink component band ofcomponent band 2 is set sets PUCCH areas from the end of the uplinkcomponent band of component band 2 in order of the PUCCH areacorresponding to the downlink component band of component band 2, thePUCCH area corresponding to the downlink component band of componentband 1 closest to the carrier frequency of the downlink component bandof component band 2 and the PUCCH area corresponding to the downlinkcomponent band of component band 0 farthest from the carrier frequencyof the downlink component band of component band 2.

In the uplink component band of component band 1 located in the centerof a plurality of component bands in FIG. 7, (that is, component bandadjacent to component band 0 and component band 2), PUCCH areascorresponding to the respective downlink component bands are set fromthe end of the uplink component band in order of component band 1,component band 2 and component band 0 as in the case of setting method 1in FIG. 6. However, in the uplink component band of component band 1,PUCCH areas corresponding to the respective downlink component bands maybe set from the end of the uplink component band in order of componentband 1, component band 0 and component band 2. Furthermore, as in thecase of Embodiment 1, terminal 200 sets the starting position of thePUCCH area corresponding to each downlink component band to be variablebased on CFI information.

Here, in the initial stage of introduction of an LTE-A system, a case isconceivable where there are many terminals of limited bandwidth (e.g.40-MHz band). For example, in FIG. 7, if the reception bandwidth isassumed to be 20 MHz per component band, a case is conceivable wherethere are many terminals that receive downlink data using only twocontinuous downlink component bands (40 MHz band). In this case,according to the present setting method, there is a high possibilitythat two PUCCH areas corresponding to two continuous downlink componentbands may be arranged in neighboring bands within the uplink componentband and arranged together at an end of the uplink component band.

For example, in FIG. 7, when two downlink component bands of componentband 1 and component band 2 are set in terminal 200 and one of uplinkcomponent bands of component band 1 and component band 2 is set,terminal 200 sets the PUCCH area corresponding to each downlinkcomponent band at the end of the uplink component band. To be morespecific, terminal 200 in which the uplink component band of componentband 1 shown in FIG. 7 is set sets PUCCH areas corresponding to therespective downlink component bands at the end of the uplink componentband in order of component band 1 and component band 2. Similarly,terminal 200 in which the uplink component band of component band 2shown in FIG. 7 is set sets PUCCH areas corresponding to the respectivedownlink component bands at the end of the uplink component band inorder of component band 2 and component band 1. Thus, in each uplinkcomponent band, it is possible to set an unused PUCCH area (here, PUCCHarea corresponding to the downlink component band of component band 0)in a band inside the uplink component band, and thereby secure morecontinuous resources for PUSCHs.

Furthermore, the terminal having a limited reception bandwidth canappropriately set PUCCH areas (ACK/NACK resources) to which ACK/NACKsignals corresponding to downlink data directed to the terminal areallocated without knowing CFI information of the downlink component bandother than the reception bandwidth of the terminal. For example, in FIG.7, when two downlink component bands; component band 1 and componentband 2 are set in terminal 200, terminal 200 can set PUCCH areas of theuplink component band (component band or component band 2) based on onlyCFI information of component band 1 and component band 2 without knowingCFI information of component band 0.

Thus, according to the present setting method, even when there are manyterminals having limited reception bandwidths, there is a highpossibility that PUCCH areas are used in order starting from the one setat the end of each uplink component band. That is, since PUCCH areas notused by terminals having limited reception bandwidths are set in a bandinside the uplink component band, it is possible to secure continuouswideband resources as PUSCH resources.

Furthermore, in the present setting method, PUCCH areas corresponding tothe downlink component band associated with the uplink component bandsare set at the end of the uplink component band rather than the PUCCHareas corresponding to the downlink component band other than thedownlink component band associated with the uplink component band.Furthermore, as in the case of Embodiment 1, terminal 200 sets thestarting position of the PUCCH area corresponding to each downlinkcomponent band to be variable based on CFI information. Therefore,according to the present setting method, as in the case of settingmethod 1, even when LTE-A terminals and LTE terminals coexist, it ispossible to reduce PUCCH areas while supporting LTE terminals in eachuplink component band as in the case of Embodiment 1.

A case has been described in the present setting method where the numberof component bands in the system is three (FIG. 7). However, in thepresent invention, the number of component bands of the system is notlimited to three. For example, a case where the number of componentbands of the system is four will be described. Here, suppose each uplinkcomponent band of component band 0 to 4 is associated with each downlinkcomponent band (not shown). Therefore, in the uplink component band ofcomponent band 0, PUCCH areas corresponding to the respective downlinkcomponent bands are set from the end of the uplink component band inorder of component bands 0, 1, 2 and 3. Similarly, in the uplinkcomponent band of component band 1, PUCCH areas corresponding to therespective downlink component bands are set from the end of the uplinkcomponent band in order of component bands 1, 0, 2 and 3 (or componentbands 1, 2, 0 and 3). Similarly, in the uplink component band ofcomponent band 2, PUCCH areas corresponding to the respective downlinkcomponent bands are set from the end of the uplink component band inorder of component bands 2, 1, 3 and 0 (or component bands 2, 3, 1 and0). Similarly, in the uplink component band of component band 3, PUCCHareas corresponding to the respective downlink component bands are setfrom the end of the uplink component band in order of component bands 3,2, 1 and 0.

PUCCH area setting methods 1 and 2 according to the present embodimenthave been described so far.

Even when LTE terminals coexist with LTE-A, the present embodiment canreduce PUCCH areas (number of ACK/NACK resources) in the uplinkcomponent band without increasing signaling while supporting the LTEterminals as in the case of Embodiment 1.

The present embodiment has described the system in which the uplinkcomponent band and the downlink component band are symmetric. However,the present invention is also applicable when the uplink component bandand the downlink component band are asymmetric. For example, as shown inFIG. 8, when uplink component bands (two uplink component bands) anddownlink component bands (three downlink component bands) areasymmetric, a certain uplink component band (component band 1 in FIG. 8)may be associated with a plurality of downlink component bands(component bands 1 and 2 in FIG. 8). In this case, the starting positionof the PUCCH area corresponding to each downlink component band isnotified to the terminal with SIB2 of the downlink component bands ofcomponent bands 1 and 2 shown in FIG. 8. In this case, as shown in FIG.8, in the uplink component band of component band 1, the terminalfixedly sets PUCCH areas corresponding to the respective downlinkcomponent bands of component band 1 and component band 2 based on thestarting position of a PUCCH area notified with SIB2 of each downlinkcomponent band. On the other hand, the terminal sets the PUCCH areascorresponding to the downlink component band other than the downlinkcomponent band associated with the uplink component band of componentband 1 (component band 0 in FIG. 8) to be variable as in the case ofaforementioned setting method 1 or setting method 2.

In FIGS. 6 to 8, the starting position of a PUCCH area notified withSIB2 need not always be the end of the band of the uplink component bandand the base station can freely set it. For example, according to LTE,the base station provides an offset corresponding to fixed resourcesused to transmit CQI information set by a parameter called N_(RB) ⁽²⁾and then sets a PUCCH area for ACK/NACK signals. In this case, bysetting resources for transmission of CQI information that needs to besecured fixedly at the end of the band of the component band, it ispossible to secure more continuous and wider resources for PUSCHs as inthe case of the above described effects.

Embodiment 3

In the present embodiment, a base station sets common CFI informationamong a plurality of downlink component bands.

Control section 102 of base station 100 according to the presentembodiment (FIG. 1) uniformly allocates downlink data directed to eachterminal among a plurality of downlink component bands set in eachterminal and thereby performs control so that the number of CCEs used toallocate downlink data becomes uniform among a plurality of downlinkcomponent bands. That is, control section 102 equalizes the number ofOFDM symbols used for transmission of PDCCH signals among all downlinkcomponent bands. Thus, control section 102 sets common CFI informationamong the plurality of downlink component bands. Control section 102then outputs the set CFI information to PCFICH generation section 106.

PCFICH generation section 106 generates PCFICH signals based on CFIinformation inputted from control section 102, that is, common CFIinformation among the respective downlink component bands.

Next, details of operations of base station 100 and terminal 200according to the present embodiment will be described. Here, as shown inFIG. 9, a case will be described where the number of component bands ofthe system is two. Furthermore, base station 100 sets two downlinkcomponent bands of component band 0 and component band 1 and an uplinkcomponent band of component band 0 for terminal 200.

As shown in FIG. 9, control section 102 of base station 100 sets commonCFI information in the respective downlink component bands of componentband 0 and component band 1.

Furthermore, control section 102 sets to k, the number of CCEs availablein the downlink component bands of component band 0 and component band 1set in terminal 200. That is, control section 102 uniformly sets thenumber of CCEs available in the respective downlink component bands forterminal 200. Thus, allocation section 105 allocates PDCCH signals ofthe respective downlink component bands to one of CCEs #1 to #k of thedownlink component band of component band 0 and CCEs #1 to #k of thedownlink component band of component band 1 set in terminal 200.

Mapping section 214 of terminal 200 then maps ACK/NACK signalscorresponding to downlink data allocated using CCEs #1 to #k ofcomponent band 0 shown in FIG. 9 and ACK/NACK signals corresponding todownlink data allocated using CCEs #1 to #k of component band 1 shown inFIG. 9 to PUCCH areas associated with the respective downlink componentbands.

Here, PUCCH areas (ACK/NACK resources) used for transmission of ACK/NACKsignals corresponding to the downlink data allocated using CCEs of therespective downlink component bands are calculated according to equation2 of Embodiment 1. Here, the number of CCEs N_(CCE)(i) available in adownlink component band of component band i in a certain subframe can becalculated according to next equation 3 instead of equation 1 ofEmbodiment 1.

N _(CCE)(i)=(L _(com) *N _(RE) _(—) _(total−N) _(RS) −N _(PCFICH) −N_(PHICH))/N _(RE) _(—) _(CCE)  (Equation 3)

Here, L_(com) represents common CFI information (e.g. L_(com)=1 to 3)among a plurality of downlink component bands. That is, equation 3 is anequation where L(i) of equation 1 is replaced by L_(com) (common CFIinformation).

For example, a reception error of a PCFICH signal of a certain downlinkcomponent band may occur out of a plurality of downlink component bands(component bands 0 and 2 in FIG. 9) set in terminal 200. Here, when thebandwidths of the respective downlink component bands are the same, themaximum number of CCEs (number of CCEs available in each downlinkcomponent band) calculated based on CFI information of each downlinkcomponent band is also the same. For this reason, in each uplinkcomponent band (component band 0 in FIG. 9), the size of the PUCCH areacorresponding to each downlink component band (k ACK/NACK resources inFIG. 9) is the same.

Thus, base station 100 sets common CFI information for each downlinkcomponent band, and even when a reception error occurs in a PCFICHsignal of the downlink component band, if terminal 200 can normallydecode PCFICH signals of one downlink component band other than thedownlink component band in which the reception error has occurred, it ispossible to identify PCFICH signals of all downlink component bands.That is, terminal 200 may use CFI information of any downlink componentband when setting PUCCH areas corresponding to the respective downlinkcomponent bands. In the downlink component band in which terminal 200has successfully received a PDCCH signal, CFI information has beenreceived normally. That is, upon successfully receiving a PDCCH signalof the downlink component band, terminal 200 can identify the PUCCH areacorresponding to the downlink component band set in the terminal.

Therefore, even when a reception error of a PCFICH signal in a certaindownlink component band occurs, terminal 200 can prevent an ACK/NACKsignal corresponding to a PDSCH signal in a certain downlink componentband from being transmitted with an erroneous PUCCH area and basestation 100 can prevent collision of ACK/NACK with other terminals.

Even when the bandwidths of the respective downlink component bandsdiffer from each other, base station 100 may notify informationindicating the bandwidth of each downlink component band to eachterminal. Furthermore, base station 100 allocates a number of CCEsgenerally proportional to the bandwidth to each component band andthereby sets a common CFI among component bands having differentbandwidths. By this means, each terminal can identify PUCCH areascorresponding to other downlink component bands based on CFI informationof a downlink component band in which the PDCCH signal has been receivednormally and information indicating a bandwidth of each downlinkcomponent band. Thus, even when the bandwidths of the respectivedownlink component bands differ from each other, terminal 200 canprevent transmission of ACK/NACK signals to a PDSCH signal in a downlinkcomponent band with wrong PUCCH areas.

Furthermore, when a certain downlink component band out of a pluralityof downlink component bands set in terminal 200 is in DRX (DiscontinuousReception: data non-reception), terminal 200 needs to receive CFIinformation (PCFICH signal) of the downlink component band in DRX to setthe PUCCH area in the uplink component band associated with the downlinkcomponent band. Furthermore, a terminal having a limited receptionbandwidth cannot receive CFI information of the downlink component bandin DRX simultaneously with CFI information of other downlink componentbands. However, by setting CFI information common to the respectivedownlink component bands, terminal 200 can identify CFI information ofthe downlink component band in DRX based on the CFI information of thedownlink component band other than the downlink component band in DRX.

Thus, even when there is a downlink component band in DRX, terminal 200can set a PUCCH area corresponding to each downlink component bandwithout receiving CFI information in the downlink component band in DRX.That is, terminal 200 need not stop DRX in the downlink component bandin DRX to receive CFI information, and can thereby prevent the powerreduction effect of DRX from deteriorating. Furthermore, even whenterminal 200 having a limited reception bandwidth cannot receive CFIinformation in a downlink component band in DRX simultaneously with CFIinformation of other downlink component bands, terminal 200 can identifythe CFI information of the downlink component band in DRX based on theCFI information of other downlink component bands.

Thus, according to the present embodiment, using common CFI informationamong a plurality of downlink component bands, it is possible to reduce,even when the terminal cannot receive CFI information of a certaindownlink component band, PUCCH areas (number of ACK/NACK resources) inan uplink component band without increasing signaling as in the case ofEmbodiment 1.

Furthermore, according to the present embodiment, the base station setscommon CFI information among a plurality of downlink component bands andalso allocates downlink data directed to a plurality of terminals. Forthis reason, through averaging effects, data is allocated substantiallyuniformly among a plurality of downlink component bands. Thus, even whenthe base station sets common CFI information among a plurality ofdownlink component bands, there will be almost no deterioration inthroughput.

Embodiment 4

A PDCCH arranged in each downlink component band includes not onlyresource allocation information (RB allocation information) directed toeach terminal but also MCS (Modulation and Coding Scheme) information,HARQ (Hybrid Automatic Retransmission reQuest) information and PUCCH TPC(Transmission Power Control) bit for controlling transmission power ofthe PUCCH or the like. Here, when a plurality of ACK/NACK signalscorresponding to downlink data transmitted in a plurality of downlinkcomponent bands are transmitted from one uplink component band, theterminal needs only to receive a notification of the PUCCH transmissionpower control bit from the downlink component band associated with theuplink component band although the PUCCH transmission power control bitis not notified from the plurality of downlink component bands.

On the contrary, when the PUCCH transmission power control bit isnotified from the plurality of set downlink component bands, theterminal may simultaneously receive a plurality of PUCCH transmissionpower control bits in a plurality of downlink component bands andthereby may not be able to appropriately perform transmission powercontrol of the PUCCH. Here, the PUCCH transmission power control bit isrepresented by a relative value (e.g. −1 dB, 0 dB, +1 dB, +2 dB) withrespect to transmission power at the time of previous transmission.

Therefore, when, for example, the PUCCH transmission power control bitsof two downlink component bands show −1 dB respectively, the terminaltransmits the PUCCH with transmission power of −2 dB. On the other hand,when the PUCCH transmission power control bits of the two downlinkcomponent bands show −1 dB, if a reception error of one PUCCHtransmission power control bit occurs, the terminal transmits the PUCCHwith transmission power of −1 dB. Thus, when the PUCCH transmissionpower control bits are notified from a plurality of downlink componentbands, the terminal may not appropriately perform transmission powercontrol of the PUCCH.

Thus, according to the present embodiment, the base station notifies CFIinformation of other downlink component bands using the field of thePUCCH transmission power control bit of a PDCCH of a certain downlinkcomponent band to a terminal in which a plurality of downlink componentbands are set. To be more specific, the base station allocates CFIinformation of the downlink component band associated with the uplinkcomponent band set in the terminal to the field of the PUCCHtransmission power control bits of the PDCCHs arranged in the downlinkcomponent band other than the downlink component band associated withthe uplink component band set in the terminal out of a plurality ofdownlink component bands set in the terminal.

Control section 102 of base station 100 according to the presentembodiment (FIG. 1) allocates the PUCCH transmission power control bitcorresponding to the uplink component band set in the terminal to thefield of the PUCCH transmission power control bits of the PDCCHsarranged in the downlink component band associated with the uplinkcomponent band set in the terminal to which resources are allocated. Onthe other hand, control section 102 allocates the CFI information of thedownlink component band associated with the uplink component band set inthe terminal to the field of the PUCCH transmission power control bitsof the PDCCHs arranged in the downlink component band other than thedownlink component band associated with the uplink component band set inthe terminal to which resources are allocated.

PDCCH receiving section 209 of terminal 200 according to the presentembodiment (FIG. 2) blind-decodes a PDCCH signal inputted fromdemultiplexing section 205 and obtains a PDCCH signal directed to theterminal. Here, PDCCH receiving section 209 decides contents of controlinformation allocated to the field of the PUCCH transmission powercontrol bit in the PDCCH signal depending on whether the downlinkcomponent band to which the PDCCH signal directed to the terminal isallocated is the downlink component band associated with the uplinkcomponent band set in the terminal or not.

To be more specific, PDCCH receiving section 209 extracts controlinformation allocated to the field of the PUCCH transmission powercontrol bit in the PDCCH signal as the PUCCH transmission power controlbit in the downlink component band associated with the uplink componentband set in the terminal. PDCCH receiving section 209 then outputs thetransmission power value shown in the extracted PUCCH transmission powercontrol bit to RF transmitting section 217 (not shown).

On the other hand, PDCCH receiving section 209 extracts the controlinformation allocated to the field of the PUCCH transmission powercontrol bit in the PDCCH signal as CFI information of the downlinkcomponent band associated with the uplink component band set in theterminal in the downlink component band other than the downlinkcomponent band associated with the uplink component band set in theterminal. PDCCH receiving section 209 then outputs the extracted CFIinformation to mapping section 214.

Mapping section 214 maps an ACK/NACK signal inputted from modulationsection 211 to a PUCCH arranged in the uplink component band based onthe CFI information inputted from PCFICH receiving section 208, CFIinformation inputted from PDCCH receiving section 209 and CCE numberinputted from PDCCH receiving section 209. That is, mapping section 214sets the starting position of the PUCCH area corresponding to eachdownlink component band in the uplink component band set in the terminalbased on the CFI information of each downlink component band in the sameway as in Embodiment 1 or 2. However, upon receiving the CFI informationfrom PDCCH receiving section 209 as input, mapping section 214 uses theCFI information as CFI information of the downlink component bandassociated with the uplink component band set in the terminal. That is,terminal 200 sets PUCCH areas corresponding to a plurality of downlinkcomponent bands using CFI information of the downlink component bandassociated with the uplink component band allocated to PDCCHs in thedownlink component band other than the downlink component bandassociated with the uplink component band set in the terminal out of theplurality of downlink component bands set in the terminal.

Next, details of operations of base station 100 and terminal 200according to the present embodiment will be described. Here, as shown inFIG. 10, a case will be described where the number of component bands ofthe system is two. Furthermore, base station 100 sets the respectivedownlink component bands of component band 0 and component band 1, andthe uplink component band of component band 0 for terminal 200.Furthermore, as shown FIG. 10, the fields of various types of controlinformation such as RB allocation information, MCS information, HARQinformation and PUCCH transmission power control bit are set in thePDCCH arranged in each downlink component band.

As shown in FIG. 10, control section 102 of base station 100 allocates,for example, RB allocation information (resource allocationinformation), MCS information, HARQ information and PUCCH transmissionpower control bit to the PDCCH arranged in the downlink component bandof component band 0 associated with the uplink component band ofcomponent band 0 set in terminal 200.

On the other hand, as shown in FIG. 10, control section 102 allocates,for example, RB allocation information, MCS information, HARQinformation and CFI information (CFI0) of the downlink component band ofcomponent band 0 to the PDCCH arranged in the downlink component band ofcomponent band 1 other than the downlink component band associated withthe uplink component band of component band 0 set in terminal 200. Thatis, control section 102 allocates CFI information of the downlinkcomponent band associated with the uplink component band set in terminal200, instead of the PUCCH transmission power control bit, to the fieldof the PUCCH transmission power control bit of the downlink componentband other than the downlink component band associated with the uplinkcomponent band set in terminal 200.

On the other hand, as shown in FIG. 10, mapping section 214 of terminal200 sets the starting position of the PUCCH area corresponding to thedownlink component band of component band 1 using CFI as in the case ofEmbodiment 1 or 2. As in the case of Embodiment 2, mapping section 214sets the PUCCH area corresponding to the downlink component bandassociated with the uplink component band set in the terminal out of theplurality of downlink component bands set in the terminal at the end ofthe uplink component band rather than in the PUCCH area corresponding tothe downlink component band other than the downlink component bandassociated with the uplink component band.

Here, mapping section 214 sets the starting position of the PUCCH areacorresponding to the downlink component band of component band 1 usingCFI0 inputted from PCFICH receiving section 208 (CFI0 allocated to thePCFICH of component band 0 shown in FIG. 10) or CFI0 inputted from PDCCHreceiving section 209 (CFI0 allocated to the field of the PUCCHtransmission power control bit of the PDCCH of component band 1 shown inFIG. 10).

Thus, even when, for example, a reception error occurs in the PCFICHsignal (CFI0) of the downlink component band of component band 0 shownin FIG. 10, if terminal 200 can normally decode the PDCCH signal of thedownlink component band of component band 1, terminal 200 can identifyCFI0 of the downlink component band of component band 0. That is, evenwhen a reception error occurs in the PCFICH signal (CFI0) of thedownlink component band of component band 0, terminal 200 can set thestarting position of the PUCCH area of component band 1 based on CFI0.

Furthermore, the downlink component band (component band 0 in FIG. 10)associated with the uplink component band (component band 0 in FIG. 10)set in terminal 200, that is, CFI information (CFI0 in FIG. 10) of thedownlink component band for which the PUCCH area is set at the end ofthe uplink component band (component band 0 in FIG. 10) is notifiedthrough the PDCCH of the other downlink component band (component band 1in FIG. 10). Thus, even when terminal 200 fails to receive the PCFICHsignal of the downlink component band (component band 0 in FIG. 10) inwhich the PUCCH area is set at the end of the uplink component band, itis possible to identify CFI information of the downlink component bandcorresponding to reception the failure through the PDCCH signal of theother downlink component band (component band 1 in FIG. 10). Here, sincethe PDCCH is subjected to error detection by CRC, if the PDCCH resultsin CRC=OK, the CFI information transmitted there is accurate with anextremely high probability. On the other hand, since the PCFICH cannotbe subjected to error detection, the reliability thereof is lower thanthat of the CFI information in the PDCCH. Therefore, terminal 200preferentially uses CFI information notified in the PDCCH to identifyPUCCH resources.

Therefore, even if the reception of the PCFICH signal of the downlinkcomponent band for which the PUCCH area is set at the end of the uplinkcomponent band fails, it is possible to prevent terminal 200 fromtransmitting an ACK/NACK signal in the wrong PUCCH area and allow basestation 100 to prevent collision of ACK/NACK signals with otherterminals.

When, for example, two downlink component bands are set in terminal 200,it is possible for base station 100 to completely prevent collision ofACK/NACK signals between terminals by terminal 200 correctly receivingthe PDCCH signal (CFI0) of component band 1 shown in FIG. 10.Furthermore, when the number of downlink component bands set in terminal200 is three, and, for example, component band 2 (not shown) is used inaddition to component band 0 and component band 1 shown in FIG. 10, ifterminal 200 correctly receives the PDCCH signal (CFI0) of componentband 1 and correctly receives the PDCCH signal (CFI1) of component band2, it is possible for base station 100 to completely prevent collisionof ACK/NACK signals between terminals.

Thus, according to the present embodiment, even when a reception errorof the PCFICH signal occurs in the downlink component band associatedwith the uplink component band set in the terminal, that is, thedownlink component band for which a PUCCH area is set at the end of theuplink component band, the terminal can identify CFI information fromthe PDCCH signal that could normally be received in other downlinkcomponent bands. Thus, it is possible to reduce the probability that theterminal may set a wrong PUCCH area in each downlink component band whensetting PUCCH areas corresponding to a plurality of downlink componentbands from the end of the uplink component band in order from thedownlink component band associated with the uplink component band set inthe terminal while obtaining effects similar to those of Embodiment 2.

Furthermore, according to the present embodiment, even when a pluralityof downlink component bands are set in the terminal, it is possible toperform transmission power control of PUCCHs appropriately by using onlyone downlink component band to notify the PUCCH transmission powercontrol bit.

Furthermore, according to the present embodiment, the base stationnotifies CFI information using the field of the PUCCH transmission powercontrol bit in the PDCCH signal in addition to notifying of CFIinformation using the PCFICH signal. That is, since CFI information isnotified using an existing control channel, signaling of new controlinformation is unnecessary.

A case has been described in the present embodiment where the basestation notifies CFI information of one downlink component band usingthe field of the PUCCH transmission power control bit in the PDCCHsignal. However, according to the present invention, the base stationmay also notify CFI information of a plurality of downlink componentbands using the field of the PUCCH transmission power control bit in thePDCCH signal or notify only part of CFI information of a certaindownlink component band.

Furthermore, according to the present embodiment, when, for example, thedownlink component band of component band 0 shown in FIG. 10 is in DRX,the base station may allocate the PUCCH transmission power control bitto the field of the PUCCH transmission power control bit in the PDCCHsignal of the downlink component band of component band 1. Thus, evenwhen the downlink component band of component band 0 is in DRX, theterminal can appropriately control transmission power of PUCCHs arrangedin the uplink component band of component band 0.

Furthermore, the present embodiment has described the setting of onePUCCH in the uplink component band of component band 0 shown in FIG. 10as an example of the setting of the PUCCH area. However, the presentinvention sets the PUCCH area for the other PUCCH in the uplinkcomponent band of component band 0 and PUCCHs at both ends of the uplinkcomponent band of component band 1 shown in FIG. 10 as in the case ofthe above described embodiment.

Embodiments of the present invention have been described so far.

In the above described embodiments, the uplink component band wherebyeach terminal transmits a PUCCH signal (e.g. ACK/NACK signal) may becalled “anchor component carrier,” “reference component carrier” or“master component carrier.”

Furthermore, a case has been described in the above embodiments wherethe base station transmits a PDCCH signal directed to each terminalusing two downlink component bands. However, in the present invention,the base station may transmit a PDCCH signal to one terminal using, forexample, only one downlink component band. In this case, the terminaltransmits an ACK/NACK signal using the PUCCH area corresponding to thedownlink component band used for transmission of a PDCCH signal in theuplink component band set in the terminal as in the case of the abovedescribed embodiments. Thus, it is possible to prevent collision ofACK/NACK signals between LTE terminals using, for example, the samedownlink component band.

Furthermore, when the base station transmits a PDCCH signal in onedownlink component band for each terminal, the downlink component bandused for transmission of the PDCCH signal may be called “anchorcomponent carrier,” “reference component carrier” or “master componentcarrier.”

Furthermore, a case has been described in the above embodiments wherethe terminal transmits ACK/NACK signals using PUCCHs arranged in oneuplink component band. However, the present invention is also applicableto a case where the terminal transmits ACK/NACK signals using PUCCHsarranged in a plurality of uplink component bands.

Furthermore, band aggregation may also be called “carrier aggregation.”Furthermore, band aggregation is not limited to a case where continuousfrequency bands are aggregated, but discontinuous frequency bands mayalso be aggregated.

Furthermore, the present invention may use C-RNTI (Cell-Radio NetworkTemporary Identifier) as a terminal ID.

The present invention may perform a multiplication between bits (thatis, between CRC bits and terminal IDs) or sum up bits and calculate mod2 of the addition result (that is, remainder obtained by dividing theaddition result by 2) as masking (scrambling) processing.

Furthermore, a case has been described in the above embodiments where acomponent band is defined as a band having a width of maximum 20 MHz andas a basic unit of communication bands. However, the component band maybe defined as follows. For example, the downlink component band may alsobe defined as a band delimited by downlink frequency band information ina BCH (Broadcast Channel) broadcast from the base station, a banddefined by a spreading width when a PDCCH is arranged distributed in afrequency domain or a band in which an SCH (synchronization channel) istransmitted in a central part. Furthermore, the uplink component bandmay also be defined as a band delimited by uplink frequency bandinformation in a BCH broadcast from the base station or a basic unit ofcommunication band having 20 MHz or less including a PUSCH in thevicinity of the center and PUCCHs (Physical Uplink Control Channel) atboth ends. Furthermore, the component band may also be represented as“Component carrier.”

Furthermore, the correspondence between the uplink component band andthe downlink component band may also be defined by uplink information(ul-EARFCN: E-UTRA Absolute Radio Frequency Channel Number) in systeminformation (SIB) notified from the base station to the terminal in thedownlink component band. The uplink information in SIB is defined in3GPP TS36.331 V8.4.0.

Furthermore, n1Pucch-AN defined in 3GPP TS36.331 V8.4.0 may be used asthe starting position (resource number) of a PUCCH area notified fromthe base station to the terminal using SIB. In the uplink componentband, the value of n1Pucch-AN decreases as the PUCCH area is closer tothe outside the band (that is, the end). Furthermore, N_(PUCCH(1))defined in 3GPP TS36.211 V8.5.0 may also be defined as the startingposition of the PUCCH area or may also be notified as a relativeposition from a position offset by resource for CQI transmission N_(RB)⁽²⁾. In 3GPP TS36.211 V8.5.0, PUCCH resources used by the terminal isrepresented by the name of a variable called “n_(PUCCH) ⁽¹⁾.”

Furthermore, in the present invention, the terminal needs to graspinformation on the downlink component band in the system to identify thePUCCH area used for transmission of ACK/NACK signals (e.g. number ofdownlink component bands, bandwidth of each downlink component band ornumber (ID) of each downlink component band). In the present invention,the information on the downlink component band may be notified with SIBor notified for each terminal. When the information on the downlinkcomponent band is notified for each terminal, the base station maynotify only information of the downlink component band in which thePUCCH area outside the PUCCH area corresponding to the downlinkcomponent band used (or may be used) by the terminal is set in theuplink component band set in the terminal. Thus, the terminal canidentify the starting position of the PUCCH area corresponding to eachdownlink component band and suppress the amount of information on thedownlink component band notified from the base station to the terminalto a necessary minimum.

Furthermore, the present invention may limit the number of downlinkcomponent bands for which PUCCH areas can be set in one uplink componentband. For example, in a system having four downlink component bands andfour uplink component bands, the downlink component bands and uplinkcomponent bands may be divided into two sets composed of two downlinkcomponent bands and two uplink component bands respectively. This limitsthe number of downlink component bands for which PUCCH areas can be setin one uplink component band to two. In this case, ACK/NACK signals fordownlink data transmitted in three or more downlink component bands aretransmitted in different sets of two uplink component bands.

Furthermore, a case has been described in the above embodiments wherethe terminal transmits a plurality of ACK/NACK signals corresponding todownlink data transmitted in a plurality of downlink component bandsusing different PUCCH areas for each downlink component band. However,the present invention is also applicable to a case where the terminaltransmits one ACK/NACK signal for downlink data transmitted in aplurality of downlink component bands (ACK/NACK bundling). Furthermore,the present invention is also applicable to a case where the terminaltransmits ACK/NACK signals for downlink data transmitted in a pluralityof downlink component bands with one PUCCH area (ACK/NACK resource)selected from among a plurality of PUCCH areas (ACK/NACK resources)(ACK/NACK channel selection or ACK/NACK multiplexing).

Furthermore, an example has been described in the above embodimentswhere PUCCH areas are set according to the number of CCEs determinedbased on CFI information. However, according to the present invention,although the relationship between CFI and the number of CCEs slightlydiffers depending on the number of antennas and the number of PHICHs foreach bandwidth of the component band, it is substantially fixed and aCFI-dependent fixed PUCCH area may be set for each bandwidth of thecomponent band. Furthermore, the bandwidth of the component band mayalso differ from one component band to another.

Furthermore, in the above embodiments, a PUCCH area of a downlinkcomponent band associated with a certain uplink component band is setfrom the end of the uplink component band. Here, RBs used for the PUCCHare assigned indices sequentially from both ends of the component band.That is, RBs are arranged in ascending order of PUCCH resource numbersstarting from both ends of the component band. Therefore, the presentinvention may set a PUCCH area of a downlink component band associatedwith a certain uplink component band in ascending order of PUCCHresource numbers.

Furthermore, broadcast information (SIB) is transmitted through achannel such as BCH, P-BCH (Primary BCH) or D-BCH (Dynamic BCH).

Also, although cases have been described with the above embodiment asexamples where the present invention is configured by hardware, thepresent invention can also be realized by software.

Each function block employed in the description of each of theaforementioned embodiments may typically be implemented as an LSIconstituted by an integrated circuit.

These may be individual chips or partially or totally contained on asingle chip. “LSI” is adopted here but this may also be referred to as“IC,” “system LSI,” “super LSI,” or “ultra LSI” depending on differingextents of integration.

Further, the method of circuit integration is not limited to LSI's, andimplementation using dedicated circuitry or general purpose processorsis also possible. After LSI manufacture, utilization of a programmableFPGA (Field Programmable Gate Array) or a reconfigurable processor whereconnections and settings of circuit cells within an LSI can bereconfigured is also possible.

Further, if integrated circuit technology comes out to replace LSI's asa result of the advancement of semiconductor technology or a derivativeother technology, it is naturally also possible to carry out functionblock integration using this technology. Application of biotechnology isalso possible.

The disclosure of Japanese Patent Application No. 2009-063031, filed onMar. 16, 2009, including the specification, drawings and abstract, isincorporated herein by reference in its entirety.

INDUSTRIAL APPLICABILITY

The present invention is applicable to a mobile communication system orthe like.

REFERENCE SIGNS LIST

-   100 Base station-   200 Terminal-   101 Setting section-   102 Control section-   103 PDCCH generation section-   104, 107, 109, 110, 211, 212 Modulation section-   105 Allocation section-   106 PCFICH generation section-   108 Broadcast information generation section-   111 Multiplexing section-   112, 215 IFFT section-   113, 216 CP adding section-   114, 217 RF transmitting section-   115, 201 Antenna-   116, 202 RF receiving section-   117, 203 CP removing section-   118, 204 FFT section-   119 Extraction section-   120 IDFT section-   121 Data receiving section-   122 ACK/NACK receiving section-   205 Demultiplexing section-   206 Broadcast information receiving section-   207 Setting information receiving section-   208 PCFICH receiving section-   209 PDCCH receiving section-   210 PDSCH receiving section-   213 DFT section-   214 Mapping section

1. A radio communication terminal apparatus that performs communicationusing a plurality of downlink component bands, the radio communicationterminal apparatus comprising: a receiving section that obtains controlformat indicator (CFI) information indicating the number of symbols usedfor a control channel to which resource allocation information ofdownlink data directed to the radio communication terminal apparatus isallocated, for each of the plurality of downlink component bands; asetting section that sets, in the uplink component band set in theterminal apparatus, a resource area to which a response signalcorresponding to the downlink data for each of the plurality of downlinkcomponent bands based on the CFI information for each of the pluralityof downlink component bands; and a mapping section that maps theresponse signal to the resource area corresponding to the downlinkcomponent band used to allocate the downlink data.
 2. The radiocommunication terminal apparatus according to claim 1, wherein thesetting section sets the resource area corresponding to the downlinkcomponent band associated with the uplink component band out of theplurality of downlink component bands at an end of the uplink componentband rather than the resource area corresponding to the downlinkcomponent band other than the downlink component band associated withthe uplink component band.
 3. The radio communication terminal apparatusaccording to claim 2, wherein the setting section sets the resourceareas corresponding to the plurality of downlink component bands inpredetermined order of downlink component bands from the downlinkcomponent band associated with the uplink component band from thestarting position of the resource area broadcast using the downlinkcomponent band associated with the uplink component band.
 4. The radiocommunication terminal apparatus according to claim 2, wherein thesetting section sets the resource areas corresponding to the pluralityof downlink component bands from the downlink component band associatedwith the uplink component band in order of closeness of downlinkcomponent bands to a carrier frequency of the downlink component bandassociated with the uplink component band from the end of the uplinkcomponent band.
 5. The radio communication terminal apparatus accordingto claim 1, wherein the setting section sets the resource areascorresponding to the plurality of downlink component bands using thecommon CFI information among the plurality of downlink component bands.6. The radio communication terminal apparatus according to claim 2,wherein the setting section sets the resource areas corresponding to theplurality of downlink component bands using the CFI information of thedownlink component band associated with the uplink component bandallocated to the control channel of the downlink component band otherthan the downlink component band associated with the uplink componentband out of the plurality of downlink component bands.
 7. A radiocommunication base station apparatus comprising: a generating sectionthat generates, for a radio communication terminal apparatus thatperforms communication using a plurality of downlink component bands,control format indicator (CFI) information indicating the number ofsymbols used for a control channel to which resource allocationinformation of downlink data directed to the radio communicationterminal apparatus is allocated for each of the plurality of downlinkcomponent bands; and a receiving section that identifies a resource areato which a response signal corresponding to the downlink data isallocated based on the CFI information for each of the plurality ofdownlink component bands in an uplink component band set in the radiocommunication terminal apparatus and extracts the response signal fromthe resource area corresponding to the downlink component band used toallocate the downlink data.
 8. A resource area setting method for aradio communication terminal apparatus that performs communication usinga plurality of downlink component bands, the method comprising:obtaining control format indicator (CFI) information indicating thenumber of symbols used for a control channel to which resourceallocation information of downlink data directed to the radiocommunication terminal apparatus is allocated for each of the pluralityof downlink component bands; and setting, in an uplink component bandset in the radio communication terminal apparatus, a resource area towhich a response signal corresponding to the downlink data is allocatedfor each of the plurality of downlink component bands based on the CFIinformation for each of the plurality of downlink component bands.
 9. Aresource area identifying method for a radio communication terminalapparatus that performs communication using a plurality of downlinkcomponent bands, the method comprising: generating control formatindicator (CFI) information indicating the number of symbols used for acontrol channel to which resource allocation information of downlinkdata directed to the radio communication terminal apparatus is allocatedfor each of the plurality of downlink component bands; and identifying,in an uplink component band set in the radio communication terminalapparatus, a resource area to which a response signal corresponding tothe downlink data is allocated based on the CFI information for each ofthe plurality of downlink component bands and extracting the responsesignal from the resource area corresponding to the downlink componentband used to allocate the downlink data.